On $g-$Fusion Frames Representations via Linear Operators

Abstract: Let ${\frak{M} k } _{ k \in \mathbb{Z}} $ be a sequence of closed subspaces of Hilbert space $H$, and let ${\Theta_k}{k \in \mathbb{Z}}$ be a sequence of linear operators from $H$ into $\frak{M}k$, $k \in \mathbb{Z}$. In the definition of fusion frames, we replace the orthogonal projections on $\frak{M} _k$ by $\Theta_k$ and find a slight generalization of fusion frames. In the case where, $\Theta_k$ is self-adjoint and $\Theta_k(\frak{M} _k)= \frak{M} _k$ for all $k \in \mathbb{Z}$, we show that if a $g-$fusion frame ${(\frak{M} _k, \Theta_k)}{k \in \mathbb{Z}}$ is represented via a linear operator $T$ on $\hbox{span} {\frak{M} k}{ k \in \mathbb{Z}}$, then $T$ is bounded; moreover, if ${(\frak{M} k, \Theta_k)}{k \in \mathbb{Z}}$ is a tight $g-$fusion frame, then $T$ is not invertible. We also study the perturbation and the stability of these fusion frames. Finally, we give some examples to show the validity of the results.